The role of zooplankton in cyanobacteria bloom development in Australian reservoirs Ying Hong B.SC & M.SC (Ecology) Submitted in fulfilment of the requirements for the degree of Doctor of Philosophy, Plant Functional Biology and Climate Change Cluster, School of Environment University of Technology, Sydney June 2013 CERTIFICATE I certify that the work presented in this thesis and the research to which it pertains, are the product of my own work and to the best of my knowledge, original. Any quotations ideas or work conducted by others published or otherwise, are fully acknowledged in accordance with the standard referencing practices of the discipline. Co-authors of published, submitted papers or articles in preparation have been acknowledged for their contributions and for each publication herein, my personal contribution and role clearly described. Furthermore, I certify that this has not previously been submitted, in completely or in part, for a degree at this or any other university. Signed ________________________ Ying Hong (Ph D Candidate) i ACKNOWLEDGEMENTS I would first like to acknowledge and immensely thank UTS International Research Scholarship, seqwater and the Plant Functional Biology and Climate Change Cluster at UTS for supporting my studies with both finances and materials during the past three and half years. I want to express my gratitude to my principle supervisor, Dr. Martina Doblin, for giving me the opportunity to work with her and for her unreserved and committed guidance. Because of her dedicated assistance, I was able to come this far. My sincere thanks to Dr. Peter Ralph, my co-supervisor, who directed my research projects. Additionally, much appreciation is due to my co-supervisor, Dr. Michele Burford, for always being available to answer my experimental and field study questions. I am also very grateful to Dr. Tsuyoshi Kobayashi at NSW Office of Environment and Heritage for his assistance with zooplankton taxonomy and experimental design. Thank you to Dr. Jessica Hill at UTS and Timothy Davis at Griffith University for their guidance in molecular techniques and to Ann Chuang at seqwater for introducing me to the world of zooplankton. Further, Prof. Iain Suthers and Dr. Jason Everett provided me with support in zooplankton analysis with the OPC at UNSW, and Dr. Ellen Van Donk and Dr. Steven Declerck shared with me their time, inspiring discussions and their experiments when I visited Netherlands Institute of Ecology; thank you all. This research would not have been possible without the outstanding help I received in data and fieldwork. Thanks to B. Reynolds and D. Gale at seqwater for retrieving historical data to aid my understanding of research questions. I owe a very special thanks to I. Taylor, J. Singleton, S. Slamet and C. Buckley for always driving the boat and helping me with the Manly Dam collections for 2 consecutive years. Additionally, many thanks go to Stephen Faggotter, Matthew Whittle, and Matthew Prentice at Griffith University for their assistance with the Wivenhoe Dam field collections. ii I am indebted to my family and friends, especially my husband and son, for standing by me and supporting me during these four years. Also, to all the brothers and sisters of Living Water Chinese Congregational Church: thank you for your consistent prayers and words of encouragement, especially thanks to Jason Zhang for his art work for conceptual models in Chapter 6. Lastly but above all I would like to thank my God. Had it been without His help and His will I could have done nothing. iii SUMMARY Cyanobacteria occupy diverse aquatic habitats and their ecological success is expected to increase under predicted future climate scenarios. Managing cyanobacteria abundance in freshwaters is therefore critical for reducing risks to human and animal health. One species that is currently undergoing range expansion from subtropical to temperate habitats is Cylindrospermopsis raciborskii. C. raciborskii is ecologically successful because of its (1) competitive nutrient acquisition and storage mechanisms (e.g. high affinity for phosphorus (P) and ammonium, high P-storage capacity); (2) wide thermal tolerance, superior shade tolerance and buoyancy regulation; (Briand et al. 2002) and (3) resistance to grazing. To date, research to understand the formation of C. raciborskii blooms and toxicity have mostly focused on environmental factors, but the importance of food web interactions in regulating blooms has been little investigated. In particular, there is a need to examine these foodweb interactions in subtropical systems in the Southern Hemisphere because much of the current understanding about zooplankton-cyanobacteria interactions comes from temperate systems dominated by large-bodied cladocerans. Given that warmer subtropical systems are dominated by copepods and smaller-bodied individuals, it is likely that interactions between zooplankton and phytoplankton have different outcomes for cyanobacterial bloom formation. To understand the mechanisms of toxic cyanobacterium C. raciborskii bloom formation in subtropical oligotrophic Australian lakes, a series of investigations were undertaken across multiple spatial and temporal scales to test the hypothesis that C. raciborskii growth is facilitated by meso-zooplankton. Specifically, small-scale laboratory experiments (~100 ml) examined zooplankton grazing and tested whether copepods avoid consumption of C. raciborskii under food saturating conditions (Chapter 2). Both the direct (grazing) and indirect (nutrient regeneration) effects of zooplankton on C. raciborskii were further examined in laboratory experiments (Chapter 3). These laboratory experiments were then scaled up to mesocosms (~500 litres), where in situ C. raciborskii growth was examined under different treatments (control, 1x and 5x ambient zooplankton abundance, 5x ambient zooplankton iv abundance + inorganic P) (Chapter 4). Comparisons between zooplankton populations were also made at the reservoir scale, testing to see whether lakes experiencing C. raciborskii blooms had different zooplankton biomass, size structure and functional group composition compared to lakes that do not experience blooms (Chapter 5). In Chapter 2, the hypothesis that copepod consumers discriminate against C. raciborskii was tested. Experiments were designed based on observed seasonal variation in food quantity and quality for zooplankton in subtropical Australian lakes and reservoirs, and tested whether clearance rates were dependent on the P-content of prey, the proportion of C. raciborskii present and the previous feeding history of zooplankton. The results indicated that the clearance rates of copepods on C. raciborskii were 2-4 times lower than that of a cladoceran Ceriodaphnia sp. when both grazers had prey choice. The copepod Boeckella sp. was found to select against C. raciborskii when alternative food was abundant, but selectivity declined when animals had been kept in low food conditions for 2-12 hours before experimentation. The clearance rates of Boeckella sp. on two toxic C. raciborskii strains were significantly lower than on a non- toxic strain. Clearance rates were also significantly lower on C. raciborskii with low cellular P content and when present at >5% relative abundance amongst natural phytoplankton assemblages. Together these results suggest that copepods largely avoid consumption of C. raciborskii. In Chapter 3, the impact of zooplankton nutrient regeneration on C. raciborskii growth was evaluated. Indirect effects of zooplankton interactions may be relatively important seasonally when dissolved nutrient concentrations are low. Dialysis experiments were designed to simultaneously test the direct (grazing) and indirect effects (nutrient regeneration) of zooplankton-algal interactions, enabling zooplankton to access food outside the dialysis tubing, and for zooplankton-derived nutrients to be accessible to algae inside the tubing. Controls with no zooplankton were also set up to account for nutrient contributions from algal prey. Zooplankton-derived nutrients alleviated P-limitation of C. raciborskii inside the dialysis tubes and stimulated growth. Furthermore, C. raciborskii growth was favoured above a green algal competitor when both algae were in dialysis tubes, indicating C. raciborskii is more efficient at taking up P recycled by zooplankton. Outside the dialysis bags, zooplankton grazed a green alga in preference to C. raciborskii and selectively consumed P-replete cells. C. raciborskii v growth was therefore affected both directly and indirectly by zooplankton, suggesting that foodweb interactions can facilitate blooms of this cyanobacterium. In Chapter 4, zooplankton regulation of C. raciborskii dominance in a natural phytoplankton community was tested at a larger scale using mesocosms deployed in a subtropical reservoir. Laboratory studies often cannot account for diversity of natural assemblages, so treatments were set up to examine C. raciborskii growth under different zooplankton densities and P loading. To the best of our knowledge, this is the first field experiment to promote C. raciborskii through zooplankton manipulation. Zooplankton enrichment resulted in an increase in C. raciborskii relative abundance from 15% to 37% after four days. Simultaneously, elevated zooplankton lowered the C:P ratio of phytoplankton, supporting the notion that copepods tend to alleviate P limitation in the environment. The generality of zooplankton-cyanobacteria interactions were examined in Chapter
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